RU2209029C1 - Method for determining vision resolution from luminous flickers frequency - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves showing light flickers of increased and reduced frequency when compared to the initial one, in turn under constant exposure time in the range of 0.5-1.5 s. The light flickers of continuously increasing increment frequency at the given constant rate of 0.5 Hz/s and continuously reducing decremental frequency at the same rate at the first stage until the testee determines difference of shown frequencies and fixes the last shown frequencies. Then light flickers of fixed frequencies are shown to the testee in turn. The light flickers of continuously reducing incremental frequency at constant rate of 0.25 Hz/s and continuously increasing decremental frequency at the same rate at the second stage until the testee determines that the flickers do not differ. Then the last fixed frequencies are shown to the testee in turn. Sequences of alternating flickers having discretely increasing incremental frequency with constant increment of 0.1 Hz at the beginning of each sequence and discretely reducing decremental frequency at the same rate are shown to the testee at the third stage until the testee determines flicker discrimination threshold on incremental and decremental frequencies and fixes the last shown frequencies. Vision resolution is determined as difference in frequency between the incremental and decremental cases recorded at the third stage. EFFECT: high accuracy of measurements. 2 dwg

Description

 The invention relates to medicine and is intended to determine the resolution of vision by the frequency of light flicker.

 Analogues of a method for determining the resolution of vision by the frequency of light flicker is not known.

 The closest in technical essence to the present invention is a method for determining the resolution of vision by the frequency of light flickers by presenting the subject with light flickers with a continuously variable frequency, and the subject being presented with flicker with a given initial frequency equal to, for example, 15 Hz, then the frequency of light flickers continuously with a speed of the order of 0.5 Hz / s they change, increasing or decreasing it, until the subject determines the subjective change in the frequency of light flicker and it will not fix their final frequency at this moment, the absolute difference between the final and initial frequencies is taken as the value of the resolution of vision in terms of the light flicker frequency [1].

 The disadvantage of the claimed method is the low accuracy of measuring the resolution of vision by the frequency of light flickering, since it is determined at a continuously changing frequency, and the human eye is more sensitive to the perception of discretely changing frequencies [2].

 The proposed method for determining the resolution of vision by the frequency of light flickers is that the test subject is presented with light flickers with a predetermined initial frequency in the visible frequency range, then alternately with a constant in the range of 0.5-1.5 with a constant time of presentation of light flickers with an increased compared with the initial - incremental frequency and reduced compared with the initial - decremental frequency, and at the first stage of measurements after the presentation of light flickers with a given initial frequency the test subject is presented with alternating light flickers with a continuously increasing incremental frequency during presentation at a given constant speed of the order of 0.5 Hz / s and continuously decreasing during the presentation with the same given constant speed of about 0.5 Hz / s decrement frequency until until the subject determines subjectively the difference between the alternate and decrement frequencies presented alternately and fixes the last presented incremental and decrement frequencies, after which the test the flicker is presented alternately with flickering of light with fixed incremental and decrement frequencies before the start of the second measurement stage; at the second stage of measurements, the test subject is presented with alternating light flickers with a continuously decreasing frequency during presentation at a given constant speed of the order of 0.25 Hz / s and continuously increasing during presentation with the same given constant speed of about 0.25 Hz / s decrement frequency to as long as the subject does not subjectively determine that the alternately presented light flickers with incremental and decremental frequencies do not differ and does not record the last presented incremental and decrement frequencies, after which the test subject is presented with alternating light flickers with incremental and decrement frequencies fixed at the second measurement stage before the third measurement stage begins; at the third stage of measurements, the test subject is presented with a series of alternating light flickers with a incrementally increasing frequency at the beginning of each series with a given constant step of 0.1 Hz and a decreasing frequency at the beginning of each series with a decrementing frequency decreasing until until the subject determines the threshold for distinguishing between alternating light flickers with incremental and decrement frequencies and fixes the last presented incremental and decrement frequencies; the resolution of vision by the frequency of light flickering is defined as the difference between the incremental and decrement frequencies recorded in the third stage.

 In FIG. 1, 2 presents time diagrams of a change in the frequencies of light flickering presented to a test subject during a measurement, and FIG. 1 is a time diagram of a change in frequencies in the first and second stages, in FIG. 2 in a third stage.

 The proposed method for determining the resolution of vision by the frequency of light flicker is as follows.

The subject is presented with light flickers with a given initial F _n frequency set in the visible frequency range, for example 15 Hz (time interval 0-T ₀ ), then alternately with a constant time of presentation of light flickers in the range 0.5-1.5 with a constant time compared with the increased with the initial F _n - incremental F _{and the} frequency and reduced compared to the initial F _n - decrement F _d frequency (time interval T ₀ -T _ISM ).

At the first measurement stage, after the presentation of light flickers with a given initial F _n frequency equal to 15 Hz (time interval 0-T ₀ ), the subject is presented with alternating light flickers with continuously increasing during presentation at a given constant speed of about 0.5 Hz / s incremental F _and frequency and continuously decreasing during presentation at the same predetermined constant speed of the order of 0.5 Hz / s decrement F _d frequency until the subject determines subjectively the difference between the presented alternately inc incremental F _and decrement F _d frequencies (time interval T ₀ -T ₁ ) and will not record the last presented incremental F _{and 1} and decrement F _d1 frequencies (time moment T ₁ ), after which the subject is presented with alternating light flickers with fixed incremental F _{and 1} and decrement F _d1 frequencies before the second measurement stage (time interval T ₁ -T ₂ ).

At the second stage of measurements, the test subject is presented with alternating light flickers with a decreasing F continuously increasing during presentation with a given constant speed of the order of 0.25 Hz / s _and a decreasing frequency continuously increasing during the presentation with the same predetermined constant speed of 0.25 Hz / s F _d to a frequency until the examinee subjectively determines that the flashing light with the incremental and decremental F _and F _d frequencies do not differ alternately requirements (time interval T ₂ -T ₃₎ and locks the the last presented incremental F _{and 2} and decremental F _d2 frequencies (time point T ₃ ), after which the subject is presented with alternating light flickers with the fixed incremental F _{and 2} and decrement F _F2 frequencies before the start of the third measurement stage (time interval T ₃ -T ₄ ).

In the third step the measurement subject is placing successive series of light flashes increasing in discrete from each batch beginning with a predetermined constant pitch of 0.1 Hz _{and the} frequency F incremental and discrete decreasing at the beginning of each series of the same predetermined constant pitch 0.1 Hz decremental frequency F _d as long as the subject does not determine the threshold discriminating imposed alternately light flashes F _and an incremental and decremental frequencies F _d (T _{4 edited} time interval T) and fix the charges last incremental _u3 w F F _g3 and decremented frequency (time T _meas). The resolution of vision by the frequency of light flickers is defined as the difference between the incremental F and ₃ and decrement F _d3 frequencies recorded in the third stage, according to the formula
ΔF = F and ₃ -F _d3 .

 The inventive method allows to determine the actual value of the resolution of vision by the frequency of light flicker and increase the accuracy of the measurements by reducing the random component of the measurement error.

 Thus, the claimed method differs from the known new properties that determine the receipt of a positive effect.

 Example.

Subject T., 22 years old, using a personal computer compatible with IBM PC, was shown through the LPT port light flickers with a predetermined initial frequency F _n equal to 15 Hz (time interval 0-T ₀ ) via the LPT port indicator, then alternately with a predetermined presentation time constant of order 1 with flashing light with increased compared with the initial F _n - F _and the incremental rate and reduced in comparison with the initial F _n - decremental frequency F _d (T _{0 edited} time interval T).

 In the process of measurement through the LPT port, the signals from the buttons "Increase in the frequency difference continuous", "Decrease in the frequency difference continuous", "Increase in the frequency difference discrete" and "Measurement" were sent to the personal computer from the remote control of the test person.

Upon receipt of a signal from the “Increase Frequency Difference Continuous” button, the computer presented alternately light flickers with incremental F _and decremental F _d frequencies, and continuously increased incremental F _and frequency during presentation at a given constant speed of 0.5 Hz / s and continuously decreased presentation time at the same predetermined constant speed of 0.5 Hz / s decrement F _{d the} frequency of light flicker. When the signal was removed from the button, the computer recorded the last presented incremental F _and and decrement F _d frequencies and presented the subject with alternating light flickers with the fixed incremental F _and and decrement F _d frequencies until the signal from the button "Decrease frequency difference continuous" was received.

Upon receipt of a signal from the button “Reducing the frequency difference continuous”, the computer presented alternately light flickers with incremental F _and decremental F _d frequencies, and continuously decreased incremental F _and frequency during presentation at a given constant speed of 0.25 Hz / s and continuously increased presentation time at the same predetermined constant speed of 0.25 Hz / s decrement F _{d the} frequency of light flicker. When the signal was removed from the button, the computer recorded the last presented incremental F _and and decrement F _d frequencies and presented the subject with alternating light flickers with the fixed incremental F _and and decrement F _d frequencies until the signal from the "Increase frequency difference increase" button was received.

Each time a signal was received from the “Increase the frequency difference discrete” button, the computer presented a series of alternating light flickers with incremental F _and decrement F _d frequencies, and discretely increased incremental F _and frequency at the beginning of each series with a given constant step of 0.1 Hz and discretely decreased at the beginning of each series with the same given constant step of 0.1 Hz, the decrement F _{d the} frequency of light flicker.

Upon receipt of a signal from the Measurement button, the computer recorded the last presented incremental F _and decrement F _d frequencies, calculated the threshold value ΔF equal to the difference between these frequencies, and displayed ΔF on the monitor screen, then presented the subject with light flickers with a given initial F _n frequency equal to 15 Hz.

At the first stage of measurements, the computer presented the subject with light flickers with a given initial F _n frequency equal to 15 Hz (time interval 0-T ₀ ). At time T ₀ the test button locked "Increased frequency difference continuous" and held in its closed state as long as the difference between the determined subjectively imposes alternately of light flashes with an incremental and decremental F _and F _d frequencies (time interval T ₀ -T ₁ ), after which he pressed the button (time moment T ₁ ). In this case, the computer recorded the last presented incremental F _{and 1} and decrement F _d1 frequencies and presented the subject with alternating light flickers with fixed incremental F _{and 1} and decrement F _d1 frequencies (time interval T ₁ -T ₂ ).

In the second phase of measurement at time T ₂ test locked button "Reducing the frequency difference continuous" and hold it in the closed state as long as the determined subjectively that imposed alternately lighting flicker with incremental F _u and decremental F _d frequencies are not distinguished ( the time interval T ₂ -T ₃ ), and then pressed the button (time T ₃ ). In this case, the computer recorded the last presented incremental F _{and 2} and decrement F _d3 frequencies and presented the subject with alternate light flickers with fixed incremental F _{and 2} and decrement F _d3 frequencies (time interval T ₃ -T ₄ ).

In the third stage the test measurements sequentially closing button "Increased discrete frequency difference" (time points T4, T5, ...) defined threshold discriminating imposed alternately flashing light with incremental and decremental F _and F _d frequencies (time interval T ₄ -T _meas. ) and pressed the "Measurement" button (time moment T _meas .). In this case, the computer recorded the last presented incremental F and ₃ and decremental F _d3 frequencies, calculated and displayed on the monitor screen a threshold value ΔF equal to 0.9 Hz, taken as the resolution of vision by the frequency of light flickers, and then presented the subject with light flickers with a given initial F _{n with a} frequency equal to 15 Hz.

 In accordance with the recommendations of physiologists, the subject performed a series of 10 measurements. As a result of the measurements, the following values of the resolution of vision were obtained by the frequency of light flicker in Hz: 0.9; 1.0; 1.0; 0.8; 1.0; 1.0; 0.8; 0.6; 0.6; 0.6. The arithmetic average of the measured values of the resolution of vision by the frequency of light flicker was 0.8 Hz, the standard deviation was 0.177 Hz, the confidence limits of the random component of the error of the measurement results with a confidence probability of 0.95, taking into account the student coefficient - 0.400 Hz.

 As a result of measurements made by test subject T. by a known method [1], the following values of the resolution of vision were obtained by the frequency of light flicker in Hz: 1.9; 2.2; 1.8; 1.6; 1.5; 1.3; 1.4; 1.6; 1.7; 1.8. The arithmetic average of the measured values of the resolution of vision by the frequency of light flicker was 1.7 Hz, the standard deviation was 0.262 Hz, the confidence limits of the random component of the error of the measurement results with a confidence probability of 0.95, taking into account the student coefficient, 0.593 Hz.

 The decrease in the random component of the measurement error (standard deviation) when performing measurements according to the proposed method compared with measurements performed by the known method [1], was 32%.

 To assess the reliability of reducing the random component of the measurement error, measurements were made of the resolution of vision by the frequency of light flickers according to the proposed and known methods in a group of 10 subjects, each of which performed a series of 10 measurements in each method. The decrease in the random component of the measurement error when performing measurements according to the proposed method compared with measurements made by the known method was 29-68%.

 Thus, the proposed method allows to determine the actual value of the resolution of vision by the frequency of light flicker and increase the accuracy of measurements.

Literature
1. Application 2001-114975 / 14 (015768) for the grant of a patent of the Russian Federation for an invention, MKI A 61 B 5/00. A method for determining the resolution of vision by the frequency of light flicker. / V.V. Rozhentsov, T.A. Lezhnina (RF).

 2. A.S. 1346136 USSR, MKI A 61 V 5/16. A device for studying the critical frequency of flicker fusion. / V.A. Maksimovich, V.I. Prokopets (USSR) .- 4 p.

Claims (1)

 A method for determining the resolution of vision by the frequency of light flickers by presenting the subject with light flickers with the initial frequency specified in the visible frequency range, characterized in that after the presentation of light flickers with the initial frequency, the test subject is presented alternately with the set in the range of 0.5-1.5 s constant time of presentation of light flicker with increased compared to the initial - incremental frequency, and reduced compared to the initial - decrement frequency, and at the first stage of measurements are presented alternately by light flickers with a continuously increasing increment frequency during presentation at a given constant speed of 0.5 Hz / s and a decreasing frequency continuously decreasing during presentation at the same speed until the subject determines the subjective difference between the presented frequencies and will record the last shown incremental and decrement frequencies, after which the subject is presented with alternating light flickers with fixed incremental and decrement hydrochloric frequencies before the second measurement step; at the second stage of measurements, the subject is presented with alternating light flickers with a decreasing frequency continuously decreasing during presentation at a given constant speed of 0.25 Hz / s and decrement frequency continuously increasing at the same speed until the subject determines subjectively that the flickering they differ and will not record the last incremental and decrement frequencies presented, after which the subject is presented with the last recorded incremental and decrement frequencies in turn th frequency before the start of the third stage; at the third stage, the subject is presented with a series of alternating light flickers with a incrementally increasing frequency at the beginning of each series with a given constant step of 0.1 Hz and decrementally decreasingly decreasing at the beginning of each series with the same step until the subject determines the flicker discrimination threshold with incremental and decrement frequencies and will not record the last presented frequencies; the resolution of vision is defined as the difference between the incremental and decrement frequencies recorded in the third stage.

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